Intro to geological maps - School of Earth and Environment

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School of Earth and Environment
Contents
Introduction to
Structural Geology
Workbook 3 Geological Maps
© BGS
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Contents
Contents
Introduction to geological maps
4
1. Outcrop patterns on geological maps
7
2. Cross sections16
3. Structure contours22
Acknowledgements and references
45
2
© BGS
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Contents
How to use this workbook
This workbook is intended as a refresher course
for those who have some previous experience of
geological maps. If you are completely new to
the subject it is worth having a look at some of
the textbooks in the bibliography in conjunction
with the workbook.
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Introduction to geological maps
Geological maps represent the solid geology at
the Earth’s surface unconcealed by vegetation,
soil or buildings (figure 1a).
Different rock types and formations are
illustrated by different colours and/or symbols.
Other features such as faults, mineral veins,
coal seams, marker horizons and landslips are
shown. Bedding and structural features such as
cleavage and foliations are indicated by strike
and dip or plunge and azimuth symbols (figure
1b).
There are several different types of geological
maps, the main ones being solid geology, which
show bedrock, and drift maps, which show
unconsolidated sediments such as river alluvium,
peat and glacial deposits that lie above bedrock.
Geological maps usually include stratigraphic
columns and one or more cross section (figure
1c). Stratigraphy columns show the different
formations on the map in the order of deposition,
with the oldest at the bottom and youngest at the
top. They also show their thicknesses and are
usually drawn to scale. The cross sections show
the sub-surface (and often the above-surface)
geology, as predicted from the features mapped
at the surface
Maps come in a variety of scales depending
on the amount of detail needed for different
purposes. In all cases, they will show a grid
for location (in Britain, the National Grid on
land). Points on the map are referred to using
coordinates (eastings then northings) which are
usually 6 or 8 figure references. The basic grid
square covers 100,000 metres, with northings,
for example, given as 670000mN, giving an
absolute location in metres. When working within
a map, it is usual to give 3 figures (e.g. 700N)
or 4 figures (e.g. 7000), depending on the scale
of the map. Four figure grid references specify
locations to within 10 metres. Maps covering a
larger area tend to use latitude and longitude in
addition or instead. Maps for other countries will
use other National Grids.
interaction of the geology with the topography.
At how folds, faults and unconformities form
consistent outcrop patterns and the information
that can be gained about these structures from
a map.
It then looks at how to draw cross sections,
including dealing with apparent dip. How to use
structure contours to construct cross sections
and to use structure contours to make accurate
and quantitative predictions about subsurface
geology.
Working with geological maps enhances
the ability to think in 3D and re-enforces the
relationships, both temporal and spatial, between
different geological units and structures.
This workbook looks first at the outcrop patterns
on geological maps, which form due to the
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Figure 1a: Geological map of the Snowdon area, Wales, UK. (© British Geological Survey).
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Figure 1b (left): Key to the Snowdon map. Figure 1c (right): Cross section and stratigraphic columns on the Snowdon geological map (© British Geological Survey).
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Worksheet 1: Outcrop patterns on geological maps
0m
20
0m
30
40
0m
10
0m
0m
10
20
0m
0m
0m
30
40
0m
40
0m
0m
10
0m
20
0m
30
0m
40
30
0m
m
10
20
0
If the Earth’s surface was flat, if there was no
topography, then geological maps would be
simple. They would be a direct reflection of
the underlying geology. However, topography
interacts with the geology to produce more
complex but predictable patterns.
Horizontal and vertical strata:
0m
20
0m
10
m
10
0
40
0m
20
0m
30
40
30
0m
40
0m
0m
10
0m
20
0m
Figure 2c: Beds dipping towards viewer
0m
40
2
0m
30
10
Dipping layers interact with the topography in
predictable ways. In valleys, beds will appear to
‘vee’ either up or down the valley in the direction
of dip (figure 2c and 2d). This is because the
valley side acts as an approximate cross section
– not always helpful on small scale maps but on
large scale maps and in the field this is a useful
aid in interpretation.
00
m
Dipping strata
0m
Figure 2b: Vertical beds
30
0m
Figure 2a: Horizontal beds
0m
Horizontal and vertical strata are the most
straightforward to interpret on a map. Horizontal
outcrops will always follow the topographic
contours (figure 2a), whilst vertical layers will
always form straight lines (figure 2b).
Figure 2d: Beds dipping away from viewer
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Effects of dip of beds and width
of outcrop
The width of outcrop on a map is affected by
the dip of the beds and by the steepness of the
topography.
All the beds in figure 3 have the same thickness.
Figure 3a, 3b and 3c show the effect of dip. As
the dip decreases from steeply dipping in Figure
3a to shallowly dipping in figure 3c the outcrop
on the map becomes wider and wider.
a
b
c
d
In figure 3d the beds have the same dip, but
the topography varies. Where the topography
is steepest on the hillside the outcrop is narrow,
where the topography is horizontal along the hill
top the outcrop is wider.
Figure 4 shows the Isle of Wight geological map.
The Mesozoic sediments have been folded into
a monocline with a steep dipping limb and a near
horizontal limb. Arrow A points to the shallow
dipping limb. Notice how wide the outcrop is
here and how closely the geological boundaries
Figure 3: Effects of dip of beds and steepness of topography on width of outcrop
follow the contours, indicative of beds with very
low dips. Arrow B points to the steep dipping
limb. Notice the narrow outcrop pattern and
how the geological boundaries cuts across the
topography indicating the steeper dip.
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B
A
Figure 4: Geological map of the Isle of Wight, southern England, UK. See text for details. © British Geological Survey.
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Faults on maps
Faults can occur at any angle with respect to
bedding and so the outcrop patterns produced
are not unique to any one fault type. Figure 5a
and 5b show two potential outcrop patterns for a
normal fault.
In a) the fault is parallel to the strike of the beds
and in b) the fault is perpendicular to the strike
of the beds. Figure 5b and 5c show how the
same outcrop pattern can result from different
fault movement. Most geological maps include a
symbol on the fault indicating the style of faulting.
a)
b)
Figure 6 shows the geological map for Kewick
Thrust faults are shown with a filled triangle on
their hangingwall. Strike-slip faults with half
arrows indicating the direction of movement
and normal faults are shown with a tick on the
hangingwall. Fold axial traces are also shown
on the map.
c)
Figure 5: Faults on geological maps. See text for details.
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Normal
fault
Strike-slip
fault
Antiform
Synform
Thrust
fault
Figure 6: Geological map of Keswick, northwest England, showing different types of faults and folds. See text for details. © British Geological Survey.
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Fold on maps
a)
b)
c)
d)
Figure 7 shows the different outcrop patterns for
folds. The limbs of the folds form a repeating
pattern on either side of the axial plane. For
anticlines, the oldest rocks are in core of the fold
and the rocks get younger away from the axial
trace (figure 7a). For synclines, the youngest
rocks are in the core and the rocks get older
away from the axial trace (figure 7b).
Plunging folds form the same repeating pattern as
non-plunging folds, except their limbs converge
around the axial traces. The limbs of synclines
open in the direction they plunge (figure 7c);
whilst the limbs of anticlines close in the direction
they plunge (figure 7d).
Figure 8 shows the Pemnbroke geological map
and cross section. This shows the repeating
pattern of geological units across the map typical
of folding. Note the apparent closure of the fold
is most likely related to topography as the dips
do not change along the axial trace. See figure
10 for an example of a plunging fold.
Figure 7: Folds on geological maps. See text for details.
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Figure 8: Geological map and cross section of Pembroke, southwest Wales, UK. See text for details. © British Geological Survey.
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Unconformities
Unconformities represent a break in deposition
and a period of uplift and erosion. They can cover
tens or hundreds of millions of years and tens or
hundreds of metres of strata may be removed.
Onlap:
An unconformity where the younger series of rocks
progressively onlap the older members of the
underlying series. So that younger beds of the
series above the unconformity rest directly on
the beds beneath the unconformity. Also known
as overlap.
Overstep:
Only the lowest bed of series above unconformity
rests directly on the beds beneath the
unconformity.
a)
Figure 10 is the geological map for Bristol. Here
the Triassic (orange/brown) units unconformably
over lie the folded Carboniferous (blue) units.
The two clearest folds are anticlines and are
separated by a narrow syncline largely hidden
by the Triassic sediments. The upper anticline
plunges to the east and the lower one to the west.
b)
Figure 9: a) An example of onlap. b) An example of overstep.
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Figure 10: Geological map of Bristol, southwest England, UK. See text for details. © British Geological Survey.
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Worksheet 2: Cross sections
A key goal of structural geologists is to understand
the three dimensional geometry of the rock
layers. A geological map is a two dimensional
representation of geological features on the
Earth’s surface. In order to provide a third
dimension, one or more slices through the Earth
are needed. Although cross sections are usually
vertical, there are instances where it is desirable
to project geologic structures on to a dipping
plane such as the profile plane of a plunging fold.
Cross sections show thicknesses, dip directions,
folds, faults, unconformities, sediment thickness
changes, igneous intrusions etc.
To draw a cross section, outcrop data from the
Earth’s surface are projected into the subsurface
geology. Sometimes this information can be
supplemented with seismic or well data. To be
able to draw a geologically realistic cross section
an understanding of the geometry and kinematics
of structures is needed.
A cross section should be consistent with all the
available data, although there are often several
viable interpretations of the same data.
Most cross sections are drawn to true scale, that
is, where the horizontal scale is the same as the
vertical scale. This means the true dip of the rock
units are shown. Vertical exaggeration, where
the vertical scale is increased relative to the
horizontal, is sometimes used to make a cross
section clearer. However, it also increases the
dips of the rock units exaggerating the geological
structures.
Figure 11: Cross section through the Keswick map in figure 6. © British Geological Survey.
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N
How to draw a cross section:
14°
Step 1:
Determine the line along which to draw the section.
The line of section should be representative of
the study area, be perpendicular to the major
structural feature of the area (e.g. large scale
folds or faults), cross as many structural features
as possible and run through areas with the most
data readings.
300
25
0
14°
0
20
150
0
Step 2:
Draw axes of an appropriate scale with the
topographic values. Unless there is a reason to
do otherwise, draw a true-scale section.
10
A’
A
0m
14°
0
20
25
0
15
0
14°
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 1: How to draw a cross section
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How to draw a cross section:
14°
Step 3:
Transfer the topographic information from the
map to the section. Project the height of each
topographic contour, where it crosses the line
of section, on to the section and draw in the
topography.
300
25
0
14°
0
20
150
0
10
A’
A
0m
14°
0
20
25
0
15
0
14°
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 1: How to draw a cross section
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How to draw a cross section:
14°
Step 4:
Transfer the lithological boundaries, faults etc on
to the cross section in the same way.
300
25
0
14°
0
20
150
0
15
0
10
0
20
14°
0
14°
25
Step 5:
Transfer bedding readings on to the section,
correcting for apparent dip if necessary (see figure
12). Plot the readings at the height at which they
occur, so where a reading is extrapolated from
a greater or lesser height than the topography
of the cross section plot it above or below the
topography as appropriate.
A’
A
0m
500m
400m
400m
300m
200m
14°
14°
14°
100m
0m
14°
300m
200m
100m
0m
-100m
-100m
-200m
-200m
Map 1: How to draw a cross section
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How to draw a cross section:
14°
Step 6:
Using the bedding readings as a guide, draw
in the lithological boundaries both above and
below the surface. Geology extended above
the topography is shown by dashed lines. When
drawing the section always consider what is
geologically reasonable behaviour for the layers
e.g. sudden changes in a unit’s thickness or dip
should be justifiable.
0
14°
0
20
Step 7:
Stand back and admire your work.
300
25
150
0
10
0
20
14°
25
0
15
0
14°
A’
A
0m
500m
400m
400m
300m
200m
14°
14°
14°
100m
0m
14°
300m
200m
100m
0m
-100m
-100m
-200m
-200m
Map 1: How to draw a cross section
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Apparent dip:
Where a sequence of rocks are cut by a section
which is not parallel to the maximum dip of the
beds, then the amount of dip will appear to be
less.
This is known as the apparent dip and it is always
less than true maximum dip
ap
M
So to draw an accurate cross section it is
necessary to calculate the apparent dip of the
beds that do not strike perpendicular to the
section. This is done using the equation:
vi
tan α’ = tan α cos β
ew
Be
dd
C
sero
s
p ct s
a io
to ra n
st lle
ri l
ke
ing
su
rfa
ce
Map view
are
n
dip t
Apparent
dip
β
n
ctio
e
s
ip
ss
Cro llel to d
a
par rection
di
As the section becomes more and more oblique
to the maximum dip the apparent dip will become
less and less until, where the cross section is
parallel to strike the beds, it will be zero and the
beds will appear horizontal regardless of their
true dip.
Line of cross section
parallel to dip
e
Tru
dip
App
where β is the angle between the dip direction
and the cross section; α is the angle of dip and α’
is the apparent dip.
Line of cross section
perpendicular to dip
Line of cross section
at an angle to dip
Line of cross section
at an angle to dip
Figure 12: Apparent dip illustrated as a block diagram and in map view.
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Worksheet 3: Structure contours
Structure contours connect points of equal
elevation (i.e. height or depth) on a geological
surface (e.g. bedding) in the same way
topographic contours connect points of equal
height above sea level. Structure contours
are also known as strike lines because they
run parallel to strike. Structure contours are
commonly used to contour subsurface horizons
of interest. They can be used in the field to
predict geological boundaries and used on maps
with no bedding readings to aid cross section
construction.
Figure 13a shows a bedding plane and heights
above sea level. Figure 13b shows the structure
contours as projected on to the plane. Figure
13c shows how these structure contours are
projected on to the map view and figure 13d
shows the map view.
A plane with a consistent strike and dip has
evenly spaced straight structure contours (figure
13), whilst a folded plane or a plane with irregular
dip will have folded or varyingly spaced structure
contours (figure 15).
a)
b)
N
N
m
400
400m
400m
m
300
300m
200m
300m
200m
m
200
100m
100m
m
100
c)
d)
N
N
400m
m
400
400m
m
300
300m
200m
m
200
300m
100m
m
100
200m
100m
Figure 13: Structure contours on a simple bedding plane and the map view of the bedding plane.
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How to draw structure contours:
Where a topographic contours cuts the contact
between two rock types it defines the height of
the structure contour for the contact at that point.
300
25
0
0
20
Where a topographic contour cuts back and forth
across a contact it gives several points at the
same height.
0
10
A’
A
0m
0
20
25
0
15
0
150
The red dots on map 2 are all at the same height:
250m - and so will all lie on the 250m structure
contour for the boundary between the yellow and
white units.
500m
Map 2: How to draw structure contours.
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How to draw structure contours:
Assuming that strike does not vary along the
boundary then the structure contours will be
straight lines, so the points can be joined to form
the structure contour for 250m.
300
25
0
20
0
At any point along the structure contour the
boundary is at 250m. Where the topography is
below 250m then boundary will be eroded away.
Where the topography is greater than 250m the
boundary will be underground.
0
20
0
10
25
0
15
0
150
A’
250m
A
0m
500m
Map 2: How to draw structure contours.
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How to draw structure contours:
The process is repeated for the other structure
contours. Assuming the boundary has a constant
dip then the structure contours will be evenly
spaced, meaning the structure contours can be
drawn in even where the bed does not outcrop.
300
25
0
0
20
0
20
0
10
25
0
15
0
150
A’
0m
100m
150m
200m
250m
300m
350m
400m
450m
A
500m
Map 2: How to draw structure contours.
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How to draw structure contours:
The structure contours can be used to construct
the cross section for the boundary by projecting
the heights of the structure contours, where they
cross the line of section on the map, to the same
height on the section itself.
300
25
0
0
20
0
20
0
10
25
0
15
0
150
A’
0m
100m
150m
200m
250m
300m
350m
400m
450m
A
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 2: How to draw structure contours.
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How to draw structure contours:
This process is then repeated for the other
boundaries on the map.
300
25
0
20
0
Note that in this case, because the units have
vertical thicknesses in multiples of 50m, the
same spacing as the structure contours, the
structure contours for the different boundaries
overlie each other.
0
10
A’
A
0m
0
20
25
0
15
0
150
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 2: How to draw structure contours.
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How to draw structure contours:
The completed cross section drawn using
structure contours.
300
25
0
0
20
0
10
A’
A
0m
0
20
25
0
15
0
150
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 2: How to draw structure contours.
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N
How to measure strike and dip
from structure contours.
m
Strike is measured clockwise from north. In
figure 14 the structure contours run east - west
and so have a strike of 090.
500m
θ
400
400m
m
300
300m
200m
m
200
300m
100m
m
100
To measure dip trigonometry is used. The
horizontal distance is measured from the map
and the vertical distance is the difference between
the values of structure contours. In figure 14,
the horizontal distance is 500m between the
400m and 100m structure contours. The vertical
distance the difference between the two structure
contours: 300m.
400m
dip θ = tan-1(300/500) = 31°
300m
N
500m
200m
100m
100m
Figure 14: a) Block model of structure contours on a
bedding plane. b) Map view of structure contours.
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Three point problems
So far to create structure contours we have
needed at least two points on a boundary to be
able to draw in the contour. The ‘three point
problem’ method allows structure contours to be
drawn when only three heights/depths are known
on a boundary.
300
25
B.
0
0
20
A.
150
0
15
0
10
0
20
25
0
Map 3 shows three small outcrops of a coal
seam. Outcrop A is at 150m, outcrop B at 200m
and outcrop C at 250m.
A’
A
C.
0m
500m
Map 3: Three point problem.
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Three point problems
To find the structure contours for the coal seam
a line is drawn between A and C. The mid point
of this line crosses the 200m structure contour.
Outcrop B also lies on the 200m structure
contour and therefore this structure contour can
be drawn in on the map.
300
25
B.
0
0
20
0
15
0
10
0
20
25
0
A.
150
A’
A
C.
0m
500m
200m
Map 3: Three point problem.
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Three point problems
Outcrop A lies on the 150m structure contour
and outcrop C on the 250m structure contour.
Assuming the coal seam is planar, these
structure contours can be drawn in parallel to the
200m structure contour. The rest of the structure
contours for the coal seam can be drawn in at
the same spacing across the map.
300
25
B.
0
0
20
0
15
0
20
0
10
25
0
A.
150
A’
0m
350m
C.
300m
250m
200m
150m
100m
50m
A
500m
Map 3: Three point problem.
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Three point problems
The outcrop pattern for the coal seam can
be constructed by finding where the structure
contours and topographic contours of the same
value cross. The coal seam can then be drawn in
and a cross section drawn in the usual way.
300
25
B.
0
0
20
0
15
0
20
0
10
25
0
A.
150
A’
0m
350m
C.
300m
250m
200m
150m
100m
50m
A
500m
Map 3: Three point problem.
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Structure contours on a faulted
surface
Structure contours across faulted surfaces can
be drawn in the same way as across bedding
surface. Map 4 shows a coal seam (thin black
line) and a dyke (thick dark grey line) cut by a
fault (red line).
300
25
0
0
20
0
10
0
20
25
0
15
0
150
A’
A
0m
500m
Map 4: Structure contours on a faulted surface.
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Structure contours on a faulted
surface
Structure contours can be drawn on the fault
and the coal seam in the usual manner. They
could be drawn on the dyke but as it is vertical
the structure contours would all lie on top of each
other.
300
25
0
0
20
0
15
0
10
0
20
25
0
150
A’
A
0m
500m
Map 4: Structure contours on a faulted surface.
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Structure contours on a faulted
surface
The cross section is constructed from the
structure contours.
300
25
0
0
20
0
10
A’
A
0m
0
20
25
0
15
0
150
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 4: Structure contours on a faulted surface.
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N
Structure contours on a faulted
surface
Provided the section is true scale, the throw
of the fault can be measured directly from it.
However, a single boundary cannot tell us the
displacement on the fault, information from a
second boundary is needed. The dyke shows
horizontal offset indicating the fault is an oblique
sllip fault.
300
25
0
0
20
0
10
A’
A
0m
0
20
25
0
15
0
150
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 4: Structure contours on a faulted surface.
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School of Earth and Environment
Map 5 shows another example of a faulted coal
seam. In this case the throw on the fault can
be determined from structure contours alone.
Note how the value of the coal seam structure
contours change by 200m as they cross the
fault. The coal seam to the east of the fault is
downthrown by 200m relative to the coal seam
on the west of the fault. From the map alone it is
not possible to work out whether there has been
any along strike displacement on the fault.
300m
250m
200m
150m
100m
Structure contours on a faulted
surface
50m
-50m
0m
Contents
N
300
25
0
0
20
0
20
0
10
25
0
15
0
150
A’
0m
350m
300m
250m
200m
150m
100m
50m
A
500m
Map 5: Structure contours on a faulted surface.
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School of Earth and Environment
Contents
Structure contours on a folded
surface
So far we have dealt with structure contours on a
planar surface, that is one with a constant strike
and dip. For surfaces which vary in strike and/
or dip structure contours can still be constructed.
around the fold so do the structure contours.
Figure 15b shows the map view of the fold. Note
how where the dip of the beds are steeper the
structure contours are closer together and where
the dip of the beds is shallower the structure
contours are more widely spaced.
b)
100m
200m
300m
400m
500m
Figure 15 shows a fold pair with structure
contours. As the strike of the beds varies
N
600m
700m
a)
800m
700m
800m
600m
400m
700m
500m
600m
500m
300m
200
m
100m
400m
300m
200
100
m
N
m
100m
200m
300m
400m
500m
600m
700m
800m
Figure 15: a) Block model of a fold pair. b) Map view of the same fold pair.
39
School of Earth and Environment
Contents
N
Structure contours on a folded
surface
Structure contours on a folded surface are
constructed in the same way as for a dipping
surface. This first example is for a simple, nonplunging upright fold, where the limbs have
consistent strikes and dips, making the process of
drawing the structure contours and cross section
the same as for a dipping bedding planes.
300
25
0
0
20
0
10
0
20
25
0
15
0
150
A’
A
0m
500m
Map 6: Structure contours on a folded surface.
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School of Earth and Environment
Contents
N
Structure contours on a folded
surface
The beds map 6 show the repeating outcrop
pattern of folded beds. The red dots show where
the yellow/light grey boundary crosses the 250m
topographic contour. There are two ways the
dots could be joined to form structure contours
- either east-west or north-south. However,
from the way the beds vee in the valley it can be
deduced the axial planes of the folds run roughly
north-south and so the structure contours for the
limbs must also be north-south.
300
25
0
0
20
0
10
0
20
25
0
15
0
150
A’
A
0m
500m
Map 6: Structure contours on a folded surface.
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School of Earth and Environment
Contents
N
Structure contours on a folded
surface
The structure contours for the rest of the boundary
and the yellow/dark grey boundary can be drawn
in in the usual way and projected on to the cross
section as before.
300
25
0
0
20
0
10
A’
A
0m
0
20
25
0
15
0
150
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 6: Structure contours on a folded surface.
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School of Earth and Environment
Contents
N
Structure contours on a folded
surface
Completed cross section.
300
25
0
0
20
0
10
A’
A
0m
0
20
25
0
15
0
150
500m
400m
400m
300m
300m
200m
200m
100m
100m
0m
0m
-100m
-100m
-200m
-200m
Map 6: Structure contours on a folded surface.
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School of Earth and Environment
Contents
N
Structure contours on a folded
surface
Map 7 shows a plunging syncline with structure
contours. The white structure contours are for
the yellow/pale grey boundary and the orange
structure contours are for the yellow/dark grey
boundary. The dashed line is the axial trace.
The plunge of the syncline can be calculated
from the structure contours in the same way as
dip is calculated using:
300
25
0
0
20
0
m
250
200
m
200
m
150
m
m
100
100
m
0m
150
m
10
where the vertical is the difference in the value
of the structure contours and the horizontal is
measured from the map.
Azimuth is measured clockwise from north.
25
0
20
250
m
0
15
plunge = tan-1(vertical/horizontal)
0
150
500m
Map 7: Structure contours on a plunging fold surface.
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School of Earth and Environment
Contents
Acknowledgments and references
Map sources:
Geological maps are all copyright of NERC
and BGS and have been made available via
GeoScholar.
Bibliography:
Bennison, G.M. and Moseley, K.A., 2011. An
introduction to geological structures and maps: a
practical guide. Eighth edition, Hodder education.
This module is based on the maps component
of the first year stratigraphic principles and
maps course of the Geological Sciences
degree programme at the School of Earth and
Environment, the University of Leeds.
Author: Dr Jacqueline Houghton, School of Earth
and Environment, University of Leeds.
45
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